On the new way of symmetry breaking in scalar QED and the one-loop renormalization

TL;DR

This paper introduces a novel approach to gauge symmetry breaking in a complex scalar QED model with two real scalars, analyzing its one-loop renormalization in curved spacetime using the Schwinger-DeWitt technique.

Contribution

It presents a new method of gauge symmetry breaking in scalar QED with two real scalars and studies its one-loop renormalization in curved spacetime.

Findings

New gauge symmetry breaking mechanism identified.

One-loop renormalization computed in curved spacetime.

Distinct gauge transformation structure for scalars.

Abstract

It is well known that single real scalar field does not allow gauge coupling to the Abelian vector field. Using the complex scalar model as a starting point, we construct the Abelian gauge model with two real scalars. The gauge transformations for the scalars look different (albeit equivalent) from the conventional sQED. Spitting the masses of the scalars, or the scalar self-couplings, or the nonminimal parameters of scalar-curvature interaction, we arrive at a qualitatively new way of gauge symmetry breaking. Using the Schwinger-DeWitt technique, we explore the one-loop renormalization of this new model in curved spacetime.